DE2539065A1 - CHARGING DEVICE FOR ELECTRIC STORAGE HEATING - Google Patents

Description

Charging device for an electric storage heater

The invention relates to a charging device for a electric storage heater ait a switching device, which from State of charge of the storage tank, in particular its core temperature, is affected and operated a charge switch.

It is known in such storage heating systems to use a core temperature sensor to measure the residual heat of the storage core and to use an outside temperature sensor to measure the expected heat demand and then to determine the charging time from both parameters. This leads to inaccurate results.

It is also known the heat demand that exists during the day of the room to be heated as electricity, to integrate this electricity and the amount achieved at the beginning of the low tariff period The integration value can be resolved again by a constant interrogation stream, whereby the interrogation time is used to determine the charging time can be used.

The invention is based on the object of specifying a charging device of the type described at the outset, which with very simple means enables a charging that is very precisely adapted to the heat requirement.

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ORIGINAL INSPECTED

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According to the invention, this object is achieved by a comparator which is generated by a comparison between a first signal corresponding to the preceding maximum state of charge and a second signal corresponding to the current state of charge forms a control signal for actuating the switching device, and by means of a correction device which the control signal is modified by a correction signal from at least one influencing the discharge Characteristic is dependent.

In this charging device, the respective final charging value is determined by starting from the final charging value in the previous charging period and modifying this, if necessary, by further parameters. If there are no changes in the outside temperature, the room temperature and the like, only the heat removed during the discharge period is replaced. This is achieved when the current state of charge represented by the second signal has reached the maximum state of charge of the previous charging period represented by the first signal. Such a comparison is very easy to make. Even if the parameters relevant for the discharge should have changed, the described charging gives a rough picture of the expected heat extraction in the coming discharge period after disregarding the heat consumption in the previous discharge period. Therefore, relatively small corrections are usually sufficient to determine a new maximum state of charge, which in turn then serves as a reference value for the next charge. Since the corrections only play a role for a final charging value at the end of the charging period, current parameters that occur during charging and influencing the discharge, such as the outside temperature, can also be taken into account. | A preferred embodiment is characterized by a first heating device, which measures the core temperature at the end of the charge, and a measured value memory, which stores this measured result, for the output of the first signal and through a second measuring device, which the

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Measures core temperature continuously »for the delivery of the second Signal. Here, in a very simple way, the core temperature is used to display the state of charge and the first Signal saved.

A particularly simple construction results when an expansion member influenced by the core temperature is used as the second Measuring device and a couplable at the end of charging, lockable driver is provided as the first measuring device and measured value memory. Only one expansion link takes care of it then for both measurements.

Furthermore, the expansion member and the driver can each carry a potentiometer tap and one input each of the comparator. In this way, the temperature readings are converted into voltages that are immediate can be compared with each other.

In a preferred embodiment, the switching device is a relay that is connected between a low tariff switch and the charging switch to the Metz supply line, and the Charging switch is a changeover switch which, in its rest position, places a magnetic coupling for the driver on the power supply line via a capacitor. As a result of the capacitor there the changeover switch, when it returns to its rest position at the end of the charging time, sends a current pulse to the magnetic Coupling through which the driver is shifted into the position corresponding to the core temperature at this point in time.

Furthermore, it is advantageous if the comparator actuates the switching device when the two measurement results have a predetermined difference, and when the correction device does this The difference.

It is particularly advantageous that the comparator is an electrical comparator and has at least one input via a summing circuit is fed, the one hand from the first

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or second signal and, on the other hand, is supplied by a correction signal emitted by the correction device. In the Summing circuit, the correction signal is subtracted from or added to one of the core temperature measurement results. As a result, the comparator only responds when there is a difference between the two measurement results. These The difference can be changed by the correction signal.

The correction signal can be formed, for example, by the voltage on an electrical storage device, for example a capacitor which can be charged via a network of parameters and discharged via resistors.

The parameter network can be one of the room temperature dependent two-position thermostat switch in series with a have solid resistance. It can also have a resistance that is dependent on the core temperature. Is also usable a resistance dependent on the outside temperature.

If the parameter network is supplied with alternating current, the thermostat switch and the one that is dependent on the core temperature can be used Resistance with a diode and the resistance, which is dependent on the outside temperature, with an oppositely polarized diode lie in series. This results in a voltage across the capacitor that can be controlled with the help of the thermostat switch and the of the core temperature-dependent resistance built up and by means of the resistance, which is dependent on the outside temperature is dismantled. When using NTC resistors, the voltage on the capacitor is greater, the longer the thermostat switch is switched on and the higher the core temperature and the lower the outside temperature is.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the drawing.

A storage heater 1 has a storage core 2 to which heat is supplied by means of a heating resistor 3 and which

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unregulated by convection and radiation as well as with the help of a Fan 4 gives off regulated heat. Power is supplied by means of an alternating current network whose phase line is connected to the Terminal 5 and its neutral conductor is connected to terminal 6. In the power supply line 7 to the heating resistor 3 there is a Low tariff counter 8, which is only available during the Low tariff periods is closed, a charging switch 9 designed as a changeover switch and a switch 10 which opens in the case of excess temperature in the core 2. The fan 4 is by means of a Thermostat switch 11 switched, the sensor 12 of which is exposed to room temperature.

An expansion member 13 is inserted into the storage core 2, which has a rod 14 which is inserted into the core 2 inserted tube 15 is attached. It carries a tap 16 that loops on a potentiometer 17 with a fixed Voltage U is supplied. Another tap 13 is located on a driver 19, which is firmly against the by a spring 20 Potentiometer 17 is pressed. The driver is held between two springs 21 in a recess 22 of the rod 14. He feels an electromagnetic clutch 23 assigned, when excited, the force of the spring 20 is overcome and the driver moves into a central position, predetermined by the springs 21, with respect to the recess 22. The clutch 23 is over a capacitor 24 is connected to the normally closed contact of the switch 9. If the toggle switch to the illustrated rest position goes, the clutch 23 receives a power surge that puts it into operation for a short time.

The changeover switch 9 is actuated by a relay 25 which is connected to the output of a comparator 26. The two Inputs 27 and 28 of the comparator 26 are each via one Resistors R1 and R2 are supplied with first and second signals in the form of the voltages obtained from taps 16 and 13 on Potentiometer 17 can be sensed. The output current of the comparator 26 forms a control signal for the switching device 25. With the circuit described so far, the

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Comparator 26 respond when the taps 16 and 18 are at the same level, that is, when the core temperature is the same Has reached the same value as at the end of the last recharge period.

A correction device 29 is provided in order to better adapt the final value of the core temperature to requirements. To this end there is a capacitor C2, whose voltage at point A via resistors R3 and R4, which together with the resistor E2 form a summing circuit, acts on the input 27 of the comparator. The capacitor C2 is connected through a resistor R5 and a diode D1 is charged whenever the thermostat switch 11 is closed. The longer the duty cycle, the more so the greater the heat requirement and the higher the charge at point A. A temperature-dependent resistor R6, which is the core temperature is exposed, takes into account the constant amount of unregulated heat emitted by radiation and convection in a similar way Way. The capacitor C2 is discharged on the one hand via the resistors R3 and R4 and on the other hand via a diode D2 and a temperature-dependent resistor R7 exposed to the outside temperature. Resistors R6 and R7 are practical NTC resistors. The voltage at point A is the higher, the longer the thermostat switch 11 is closed, the higher is the core temperature and the lower the outside temperature is.

The charger works in the following way. The driver 19 has saved the final temperature of the last charge. By controlled heat emission by means of the fan 4 and by unregulated heat emission due to radiation and The storage core 2 gives off heat by convection. As a result, the core temperature drops. As a result, the tap 16 moves of the rod 14 upwards. If the switch θ is switched on at the beginning of the next low tariff period, it pulls Relay 25 immediately and puts the charging switch 9 in the working position because the input 28 of the comparator 26 from The input signal coming from the tap 16 of the driver 19 is different from the signal present at the input 27. The two Input values approach each other when the heating of the

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Core 2 the core temperature rises again. The exact final value at which the relay 25 drops out again is reached when the Difference between the voltages at the taps 16 and 17 has a value that is predetermined by the voltage at point A. is. This voltage is still generated during charging by various external influences, namely the current heat emission and the outside temperature, corrected. When the charging switch 9 returns to the rest position, the clutch is briefly excited. As a result, the contact pressure is released by the spring 20 and the driver can in the current End value of the core temperature corresponding central position can be shifted. Then it is locked there again by the spring 20, to save the temperature measurement result until the next charge.

It is also possible to use the measuring devices for the state of charge and to design the measured value memory purely electrically. The corrective influence can also be asserted in other ways , for example, by intervening in the comparator itself. Instead of the capacitor C2, another electronic Component are used, which has a dependent on the charge and discharge voltage, for example a so-called "memo period".

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Claims (12)

- 8 patent claims 1. Charging device for an electric storage heater rait a switching device that depends on the state of charge of the memory, is influenced in particular by its core temperature and actuates a charging switch, characterized by a Comparator (26), the by a comparison between a corresponding to the previous maximum state of charge first signal and a second signal corresponding to the current state of charge, a control signal for actuation the switching device (25) forms, and by a correction device (29) with which the control signal by a Correction signal is modified, which is dependent on at least one parameter influencing the discharge. 2. Charging device according to claim 1, characterized by a first measuring device (19) which measures the core temperature at the end of charging, and a measured value memory (19) which stores this measurement result for the delivery of the first signal and by a second measuring device (14), which measures the core temperature continuously, for the delivery of the second Signal. 3. Charging device according to claim 2, characterized in that an expansion member influenced by the core temperature (14) as a second measuring device and a lockable driver (19) which can be coupled to it at the end of charging as the first Measuring device and measured value spei is rather provided. 4. Charging device according to claim 3, characterized in that the expansion member (14) and the driver (19) each carry a potentiometer tap (16, 18) and each with are connected to an input of the comparator (26). 5. Charging device according to claim 3 or 4, characterized in that the switching device (25) is a relay which between a low tariff switch (8) and the charging switch (9) is connected to the power supply line, and 709810/0584 that the charge switch is a toggle switch that is in his Rest position a magnetic coupling (23) for the driver (19) connects to the power line via a capacitor (C1). 6. Charging device according to one of claims 1 to 5, characterized characterized in that the comparator (26) actuates the switching device (25) when the two measurement results show a predetermined difference, and that the correction device (29) fixes this difference. 7. Charging device according to one of claims 1 to 6, characterized characterized in that the comparator (26) is an electrical comparator and at least one input is fed via a summing circuit (R2, R3, R4), which on the one hand is fed by first or second signal and on the other hand from a correction signal emitted by the correction device (29) is supplied. 8. Charging device according to claim 7, characterized in that the correction signal is formed by the voltage on an electrical storage device, e.g. a capacitor (C2), which can be charged via a parameter network (30) and via Resistors (R3, R4) can be discharged. 9. Charging device according to claim 8, characterized in that the parameter network (30) has a room temperature dependent two-position thermostat switch (11) in Series with a fixed resistance (Rj?). 10. Charging device according to claim 8 or 9, characterized in that the parameter network (30) one of the Has core temperature dependent resistance (R6). 11. Charging device according to one of claims 8 to 10, characterized characterized in that the parameter network (30) has a resistance that is dependent on the outside temperature (R7). 709810/0584 BATH ORIGINAL 12. Charging device according to one of claims 8 to 11, characterized »that when the characteristic variable network (30) is fed with alternating current, the thermostat switch (11) and the resistance (R6) dependent on the core temperature with a diode (D1) and the resistance dependent on the outside temperature Resistor (R7) with an oppositely polarized diode (D2) are in series. BATH 7098 10/0584